A full-electric drive cementing control system is disclosed. The system includes: a water supply system for supplying clear water; an ash supply system for supplying dry ash; a slurry mixing system for performing a slurry mixing operation to form slurry; a plunger pump for pumping the slurry to a cementing operation object; and a control assembly for controlling, in response to a received cementing operation instruction, connection of a pipeline between an outlet of the water supply system and an inlet of the slurry mixing system and a pipeline between an outlet of the ash supply system and the inlet of the slurry mixing system, controlling, according to a preset slurry mixing parameter, the slurry mixing system to mix the clear water and the dry ash to form the slurry required for a cementing operation, and controlling, according to a preset perfusion parameter, a driving motor to drive the plunger pump to work, the cementing operation instruction carrying the preset slurry mixing parameter and the preset perfusion parameter.

An oxygenated water producing apparatus has a filtration assembly, an oxygen dissolving assembly, a minimizing assembly, and an electrolytic assembly that communicate with one another. The filtration assembly has a water filtration device, a water softener, and a water purifier communicating with one another in series. The oxygen dissolving assembly has a cooling tank communicating with the water purifier, a pump communicating with the cooling tank, an air pipe connected to the pump, and a pressure tank communicating with the pump. The minimizing assembly has at least one minimizing device. Each minimizing device has a shell, a minimizing basket with multiple filtrating holes, and a minimizing plate with multiple meshes mounted inside the shell. The electrolytic assembly has at least one electrolytic unit. Each electrolytic unit has a tube having an inlet and an outlet, and a cathode and an anode assembled to the tube.

A device for slurrying a suspension and a method for operating such a device are disclosed. In an embodiment a device includes a mixing container with an inlet opening configured to introduce the suspension into the mixing container a distributor element having a collecting container and an outlet arm fastened to the collecting container and a shaft with a longitudinal axis, wherein the shaft and the distributor element are arranged inside the mixing container, wherein the distributor element is mounted so as to be freely rotatable around the shaft, wherein the collecting container comprises a collecting opening configured to pass the suspension from the inlet opening into the distributor element, wherein the outlet arm comprises an outflow opening configured to let the suspension leave the distributor element, and wherein the outlet arm is designed such that the suspension is able to flow out of the distributor element starting from the collecting container via the outlet arm and the outflow opening, a flow of the suspension causing a torque on the distributor element so that the torque supports a rotation around the shaft.

The present invention discloses a water heater system, comprising: a heating unit capable of heating water; a pump communicated with the heating unit; a gas inlet structure disposed on or communicated with the pump, the pump being capable of mixing a gas and water flowing into it; and a pressure regulating device disposed downstream of the pump. The water heater system provided in the present invention is applicable to scenarios of any existing water heaters, including electric water heaters, gas water heaters, solar water heaters, air-source water heaters, etc., and can produce micro-bubble water for use by the users, which is not only water saving but also environmental protective. Moreover, the micro-bubble water has a strong cleaning performance, and thereby greatly improves the user experiences.

A mixing device is configured for the continuous provision of a gelling mass for a molding machine. The mixing device includes an inlet, an outlet and a conduit section which is situated between the inlet and the outlet and into which at least one admixing conduit runs out, via which admixing conduit a substance to be admixed can be fed such that the substance to be admixed is mixed with a base mass which is fed through the inlet, in a mixing region in the conduit section. The mixing device is configured in a manner such that the spatial distance between the outlet and the mixing region in which the substance to be admixed is mixed with the base mass, can be changed. A molding machine with such a mixing device and to a method for processing a flowable and gellable mass are provided.

A thermally fused board manufacturing apparatus includes: a fiberizing section that produces a fiber material by fiberizing a raw material containing fabric; a material supply pipe section that carries the fiber material; a humidifying section configured to humidify the fiber material; a carriage pipe section that adds a material different from the fiber material to the fiber material and carries the material and the fiber material; a mixing section that produces a deposition fiber material by mixing the material and the fiber material, at part of the carriage pipe section; a depositing section that forms a fiber aggregate by depositing the deposition fiber material; a thermal fusing section that forms a thermally fused board by applying heat and pressure to the fiber aggregate; and a controller that controls the humidifying section.

A full-electric drive cementing control system is disclosed. The system includes: a water supply system for supplying clear water; an ash supply system for supplying dry ash; a slurry mixing system for performing a slurry mixing operation to form slurry; a plunger pump for pumping the slurry to a cementing operation object; and a control assembly for controlling, in response to a received cementing operation instruction, connection of a pipeline between an outlet of the water supply system and an inlet of the slurry mixing system and a pipeline between an outlet of the ash supply system and the inlet of the slurry mixing system, controlling, according to a preset slurry mixing parameter, the slurry mixing system to mix the clear water and the dry ash to form the slurry required for a cementing operation, and controlling, according to a preset perfusion parameter, a driving motor to drive the plunger pump to work, the cementing operation instruction carrying the preset slurry mixing parameter and the preset perfusion parameter.

A full-electric drive cementing control system is disclosed. The system includes: a water supply system for supplying clear water; an ash supply system for supplying dry ash; a slurry mixing system for performing a slurry mixing operation to form slurry; a plunger pump for pumping the slurry to a cementing operation object; and a control assembly for controlling, in response to a received cementing operation instruction, connection of a pipeline between an outlet of the water supply system and an inlet of the slurry mixing system and a pipeline between an outlet of the ash supply system and the inlet of the slurry mixing system, controlling, according to a preset slurry mixing parameter, the slurry mixing system to mix the clear water and the dry ash to form the slurry required for a cementing operation, and controlling, according to a preset perfusion parameter, a driving motor to drive the plunger pump to work, the cementing operation instruction carrying the preset slurry mixing parameter and the preset perfusion parameter.

An oxygenated water producing apparatus has a filtration assembly, an oxygen dissolving assembly, a minimizing assembly, and an electrolytic assembly that communicate with one another. The filtration assembly has a water filtration device, a water softener, and a water purifier communicating with one another in series. The oxygen dissolving assembly has a cooling tank communicating with the water purifier, a pump communicating with the cooling tank, an air pipe connected to the pump, and a pressure tank communicating with the pump. The minimizing assembly has at least one minimizing device. Each minimizing device has a shell, a minimizing basket with multiple filtrating holes, and a minimizing plate with multiple meshes mounted inside the shell. The electrolytic assembly has at least one electrolytic unit. Each electrolytic unit has a tube having an inlet and an outlet, and a cathode and an anode assembled to the tube.

The present invention provides a gas-containing base material that can contain and retain a functional gas with a high concentration and a method of producing the same. A method of producing a gas-containing base material including a functional-gas-containing composition includes the following processes.

Process (1):

In this process, a functional gas is supplied to a raw material composition having a gelation temperature in a range of 0.5 C. or higher and 65 C. or lower at which a liquid form is able to be changed to a solid form by cooling while the temperature is maintained at a degree at which the raw material composition is in a liquid form, and the amount of the functional gas which exceeds a saturated solubility when the raw material composition is in a liquid form is uniformly dispersed as fine bubbles

Process (2):

In this process, the liquid raw material composition in which fine bubbles of the obtained functional gas are dispersed is transferred into a filling container and the filling container is filled and sealed.

Process (3):

In this process, the liquid raw material composition in which the obtained fine functional gas bubbles in the sealed filling container are dispersed is cooled at a temperature equal to or lower than the gelation temperature of the raw material composition and solidified.